Effects of chitinolytic and proteolytic enzymes on in vitro phagocytosis of microsporidians by spleen macrophages of turbot, Scophthalmus maximus L

Transcriptomic analysis provides insights into the mechanisms underlying the resistance of Penaeus vannamei to Enterocytozoon hepatopenaei (EHP)

The Penaeus vannamei aquaculture industry is facing a significant challenge in the form of hepatopancreatic microsporidiosis (HPM) caused by Enterocytozoon hepatopenaei (EHP), resulting in substantial economic losses. However, the extent of knowledge regarding the mechanisms by which shrimp resist EHP is limited. We screened resistant and susceptible shrimp and found that resistant shrimp had lower EHP load and less tissue damage. To gain insight into the molecular mechanisms underlying the EHP resistance of shrimp, a comparison was conducted at the transcriptional level between the resistant and susceptible families. Transcriptomic analysis of shrimp hepatopancreas revealed significant differences between the resistant and susceptible families. Compared to the susceptible family, the immune system of the resistant family was activated. The resistant family showed up-regulation in the expression of cathepsin L, C-type lectin, penaeidin, chitinase genes, and metabolism of xenobiotics by cytochrome P450-related genes. Additionally, the resistant shrimp exhibited a higher capacity for amino acid uptake. The observed differences in the resistant and susceptible family transcriptome may contribute to the shrimp's resistance to EHP.

Germination of Microsporidian Spores: The Known and Unknown

Microsporidia are a large group of mysterious obligate intracellular eukaryotic parasites. The microsporidian spore can survive in the absence of nutrients for years under harsh conditions and germinate within seconds under the stimulation of environmental changes like pH and ions. During germination, microsporidia experience an increase in intrasporal osmotic pressure, which leads to an influx of water into the spore, followed by swelling of the polaroplasts and posterior vacuole, which eventually fires the polar filament (PF). Infectious sporoplasm was transported through the extruded polar tube (PT) and delivered into the host cell. Despite much that has been learned about the germination of microsporidia, there are still several major questions that remain unanswered, including: (i) There is still a lack of knowledge about the signaling pathways involved in spore germination. (ii) The germination of spores is not well understood in terms of its specific energetics. (iii) Limited understanding of how spores germinate and how the nucleus and membranes are rearranged during germination. (iv) Only a few proteins in the invasion organelles have been identified; many more are likely undiscovered. This review summarizes the major resolved and unresolved issues concerning the process of microsporidian spore germination.

Fish microsporidia: immune response, immunomodulation and vaccination

Immune response to fish microsporidia is still unknown and there are current research trying to elucidate the events involved in the immune response to this parasite. There is evidence suggesting the role of innate immune response and it is clear that adaptive immunity plays an essential part for eliminating and then mounting a solid resistance against subsequent microsporidian infections. This review article discusses the main mechanisms of resistance to fish microsporidia, which are considered under four main headings. 1) Innate immunity: the inflammatory tissue reaction associated with fish microsporidiosis has been studied at the ultrastructural level, providing identification of many of the inflammatory cells and molecules that are actively participating in the spore elimination, such as macrophages, neutrophils, eosinophilic granular cells, soluble factors and MHC molecules. 2) Adaptive immunity: the study of the humoral response is relatively new and controversial. In some cases, the antibody response is well established and it has a protective role, while in other situations, the immune response is not protective or it is depressed. Study of the cellular response against fish microsporidia is still in its infancy. Although the nature of the microsporidian infection suggests participation of cellular mechanisms, few studies have focused on the cellular immune response of infected fish. 3) Immunomodulation: glucans are compounds that can modulate the immune system and potentiate resistance to microorganisms. These compounds have been proposed that can interact with receptors on the surface of leukocytes that result in the stimulation on non-specific immune responses. 4) Vaccination: little is known about a biological product that could be used as a vaccine for preventing this infection in fish. In the Loma salmonae experience, one of the arguments that favor the production of a vaccine is the development in fish of resistance, associated to a cellular immune response. A recently proved spore-based vaccine to prevent microsporidial gill disease in salmon has recently shown its efficacy by considerably reducing the incidence of infection. This recent discovery would be first anti-microsporidian vaccine that is effective against this elusive parasite.

Non-isotopic detection of Tetramicra brevifilum (Microspora) DNA in turbot tissues

A non-isotopic in situ hybridization (ISH) method was developed for detection of Tetramicra brevifilum, a commercially important parasite in farmed turbot Scophthalmus maximus. The probe relies on sequences from the small-subunit rRNA gene (SSUrDNA) of Tetramicra brevifilum and was obtained by polymerase chain reaction then labeled with digoxigenin. The results obtained demonstrate that the probe hybridizes well with genomic DNA of the spores; thus, it is an effective method for detecting multiorgan infections of turbot by T. brevifilum.

Effect of Tetramicra brevifilum (Microspora) infection on respiratory-burst responses of turbot (Scophthalmus maximus L.) phagocytes

In vitro assays were performed to investigate microsporidian-induced intracellular and extracellular production of reactive oxygen species (ROS) by peritoneal-exudate adherent (PEA) cells from turbot. ROS production was quantified using the fluorescent reagents OxyBURST Green H2HFF BSA (extracellular) and OxyBURST Green H2DCFDA succinimidyl ester (intracellular). Five days before assay, the cells had been elicited in vivo by intraperitoneal injection of sodium thioglycollate or spores of Tetramicra brevifilum. Elicitation with spores led to a marked increase in the proportion of neutrophils among PEA cells. PEA cells from normal turbot showed considerable extracellular and intracellular ROS production in response to microsporidian spores. By contrast, PEA cells from microsporidian-infected turbot showed considerably reduced extracellular and intracellular ROS production in response to microsporidian spores. Extracellular ROS production was affected by the addition of infected turbot serum to the assay medium, regardless of whether the PEA cells had been obtained from normal or infected fish. The presence of microsporidian-infected turbot serum significantly reduced intracellular ROS production by PEA cells elicited with microsporidian spores. These results suggest that (a) microsporidian spores partially suppress the repiratory-burst response of turbot phagocytes; and (b) infected turbot serum contains substances capable of modulating the respiratory-burst response of turbot phagocytes to microsporidian spores.

Phagocytic uptake of Encephalitozoon cuniculi by nonprofessional phagocytes

Encephalitozoon cuniculi is an obligate intracellular, spore-forming parasite belonging to the microsporidia that can cause disseminated infection in immunocompromised persons. E. cuniculi spores infect host cells by germination, i.e., by explosively everting the polar filament, through which the spore contents (sporoplasms) are subsequently injected into the cytoplasm. In addition, we observed intracellular, nongerminated spores in various nonprofessional phagocytes. In MRC5 cells, the number of internalized spores was approximately 10-fold higher than the number of injected sporoplasms. Compared to the rate of uptake by human monocyte-derived macrophages, internalization rates by A549 cells, MRC5 cells, and 293 cells were 0.6, 4.4, and 22.2%, respectively. The mechanism of uptake was studied in MRC5 cells. Killed spores were internalized at the same rate as live spores, indicating that nongerminated parasites do not actively participate in cell entry. Cytochalasin D inhibited uptake of spores by 95%, demonstrating an actin-dependent process. By electron and epifluorescence microscopy, intracellular spores were found in a tightly fitting membrane-bound compartment. The vacuole containing the spores was positive for the lysosomal membrane protein LAMP-1 and colocalized with the late endosomal-lysosomal content marker rhodamine dextran. Our results show that, in addition to the unique way in which microsporidia infect cells, E. cuniculi spores enter nonprofessional phagocytes by phagocytosis and traffic into a late endosomal-lysosomal compartment.

Modulation of the in vitro activity of European sea bass (Dicentrarchus labrax L.) phagocytes by the myxosporean parasite Sphaerospora dicentrarchi (Myxosporea: Bivalvulida)

Several in vitro studies were performed to study the cellular reaction of European sea bass (Dicentrarchus labrax L.) against Sphaerospora dicentrarchi. Head kidney phagocytes were obtained from parasitised (P) and non-parasitised (NP) fish. The production of superoxide anion (O2-), tested by the NBT method, was higher in P than in NP fish. The addition of increasing amounts of sea bass serum (SBS) produced a gradual increment of the respiratory burst with SBS from parasitised animals (P-SBS), whereas this increment reached a plateau at lower concentration with SBS from nonparasitised ones (NP-SBS). O2- production was higher when adding NP-SBS than with P-SBS or fetal bovine serum. Heat inactivation of NP-SBS and FBS reduced the respiratory burst significantly, whereas it did not change the effect of P-SBS. The number of NBT-positive cells after particulate stimulation was significantly higher using S. dicentrarchi spores than using SRBC, but lower than with phorbol myristate acetate. Phagocytes primed overnight with spore extracts produced higher amounts of O2- than those LPS-primed or non-primed ones. A similar percentage of phagocytosis was detected using glutaraldehyde fixed spores and SRBC. Most of the phagocytes engulfed three or more SRBC, whereas most of the phagocytes engulfed only one spore. Complement mediated opsonisation by NP-SBS may occur, as the phagocytic index was reduced when the serum was heat inactivated.

Non-specific responses of turbot (Scophthalmus maximus L.) adherent cells to microsporidian spores

We investigated non-specific responses of turbot spleen- and pronephros-resident adherent cells to spores of fish microsporidians, and the effects of the glucocorticoid dexamethasone (DX) on these responses. On average, 65% of adherent cells from the spleen and pronephros showed esterase activity (as characteristic of macrophages); 32% showed peroxidase activity (as characteristic of neutrophils), and 19% of peroxidase-positive cells were capable of phagocytosing microsporidian spores. A significantly higher proportion of adherent cells showed phagocytic activity when viable spores were the target than when non-viable spores were the target. Microsporidian spores stimulated adherent cells to produce reactive oxygen and nitrogen intermediates (ROIs and RNIs), though less effectively than the other stimulants tested. Adherent cells exposed to viable spores produced significantly less intracellular superoxide than adherent cells exposed to non-viable spores. Daily injection of fish with DX over 6 days significantly inhibited both phagocytosis of microsporidian spores and spore-induced ROI production, and similar effects were observed when adherent cells were exposed to DX in vitro.